Quantitative measuring method and apparatus of metal phase using x-ray diffraction method, and method for making plated steel sheet using them

Abstract

A method and apparatus for quantitatively measuring a metal phase contained in a galvanized layer by X-ray diffractometry, and a method of producing a galvanized steel sheet by using the method and apparatus. The diffracted X-ray intensity from a metal phase contained in the galvanized layer is increased to improve measurement accuracy, thereby permitting application to on-line measurement. The diffracted X-rays from the metal phase are measured over a predetermined range on a Debye ring, or measured at a plurality of positions on the Debye ring to increase the diffracted X-ray intensity, thereby improving measurement accuracy. The X-ray beam produced by an X-ray source is compressed and made parallel and monochromatic by a multilayer film mirror to increase diffracted X-ray intensity, improving measurement accuracy. Particularly, the present invention is applied to measurement of the degree of alloying of hot-dip galvanization.

Description

The present invention relates to a method and apparatus for quantitatively measuring a metal phase by X-ray diffractometry, and a method of producing a galvanized steel sheet by using the method and apparatus. Particularly, the present invention relates to a method and apparatus for accurately measuring the deposit amount of a metal phase contained in a galvanized layer, particularly a desired metal phase of not less than two metal phases contained a galvanized layer, in a nondestructive state, and a method of producing a galvanized steel sheet by using the method and apparatus.The quality characteristics (pealing resistance in processing, corrosion resistance, and the like) of a plating containing alloy phases significantly vary depending upon the deposit amount of each of the alloy phases in a galvanized layer. Therefore, in order to produce a plated product of high quality, it is important to accurately measure the deposit amount of each of the phases and control production condi...

AI Technical Summary

Benefits of technology

In consideration of the above-described circumstances, an object of the present invention is to increase diffracted X-ray intensity from a metal phase contained in a galvanized layer to improve the measurement accuracy of the deposit amount of the metal phase contained in the galvanized layer. Another object of the present invention is to contribute to the production of a galvanized product of high quality. A further object of the present invention is to provide a measuring apparatus and method capable of accurately measuring the deposit amount of an alloy phase even when the distance between an X-ray diffraction position and a detection system varies with vibration of a steel sheet, like in on-line measurement of a running steel sheet.

The present invention provides a method and apparatus for measuring the deposit amount of a metal phase contained in a galvanized layer by X-ray diffractometry, the method comprising measuring diffracted X-rays from the metal phase contained in the galvanized layer over a predetermined range on a Debye ring, and integrating the obtained X-ray diffraction intensity data to permit the accurate measurement of the deposit amount of the metal phase.

The present invention also provides a method of measuring the deposit amount of a metal phase contained in a galvanized layer by X-ray diffractometry, the method comprising measuring diffracted X-rays from the metal phase at a plurality of positions on at least one Debye ring formed by the diffracted X-rays to detect large quantities of X-rays, and integrating the obtained X-ray diffraction intensity data to increase the X-ray intensity data, thereby permitting the accurate measurement of the deposit amount of the metal phase.

In the method and apparatus of the present invention, the detected X-ray intensity (total amount of X-rays detected per unit time) can be increased to improve the accuracy of measurement of the deposit amount of the metal phase.

Problems solved by technology

alues. Therefore, there is no resolution of the problem of deteriorating measurement accuracy when the obtained diffracted X-ray intensity

On-line measurement of a running steel sheet, such as on-line measurement of a steel sheet in a surface treatment step, also has a problem in which accurate measurement is made impossible by the influence of vibration of the steel sheet.

Since alloy phases having small deposit amounts, such as the .GAMMA. phase and .zeta. phase, show low diffracted X-ray intensity, the deposit amounts of these phases cannot be easily evaluated with high accuracy.

In the use of diffracted X-rays for a galvanized layer containing a plurality of metal phases, the occurrence frequency of superposition of other peaks is increased to make quantitative accurate analysis more difficult.

In this case, the time of detection by a scintillation counter cannot be extended to fail to increase the count number of diffracted X-rays, and thus the above problems become significant.

Although, in the invention of Japanese Unexamined Patent Publication No. 9-33455, the above problems are solved by setting the appropriate theoretical intensity formula, the fundamental problem of week diffracted X-ray intensity cannot be resolved.

However, the detected X-ray diffraction intensity itself is not increased.

Therefore, sufficient accuracy cannot be obtained according to the conditions of a measurement sample.

However, these diffractometers have no characteristic as an apparatus.

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